RU2781521C2 - Lock - Google Patents

Abstract

FIELD: locking systems.

SUBSTANCE: invention relates to a lock intended for locking cabinets, storages, and cars. The lock has case (1), which contains crossbar (2). Lock cylinder (3) is connected to the lock case. The lock case contains power transmission mechanism (4) between the lock cylinder and the crossbar. The power transmission mechanism contains transmission lever (7) and pawl (6). The transmission lever additionally contains retaining protrusion (8). The crossbar contains locking pin (9), and the lock case additionally contains hole (10). The lock allows for the movement of lock cylinder (3) and force transfer mechanism (4) in the direction of the longitudinal axis of the lock cylinder under action of external impacts or attempt for drilling the lock cylinder, due to which the movement in the direction of the longitudinal axis of the cylinder displaces retaining protrusion (8) from locking pin (9), and end (9A) of the locking pin enters hole (10) in the case.

EFFECT: blocking of a crossbar in a closed position is provided under impact or attempt for drilling.

9 cl, 8 dwg

Description

Field of invention

The present invention relates to locks for ATMs and other machines, cabinets and related storage that require locking.

Prior Art

It is known the use of locks, for example, in ATMs and other various machines, when only authorized persons have the right to open the lock and perform the necessary actions inside the machine, cabinet or corresponding storage. Such actions include, for example, filling an ATM with banknotes and withdrawing cash from a gas station or vending machine.

Such machines, cabinets and vaults can be the targets of robbery when attempts are made to open the lock in various ways. It is known to use a separate locking finger, also referred to as a locking finger, in such machines, cabinets and storages. The locking pin locks the deadbolt in the locked position if an external force is applied to the lock. Thus, the bolt cannot be moved out of the locking position, i.e., when its end is pulled out of the lock, it cannot be pushed into the lock. The locking finger is used to ensure that the deadbolt remains in the locking position even if the lock is tampered with.

Publication CN 206468137 U describes a lock for locking cabinets. This lock has a lock body in which a deadbolt is located, and a lock cylinder is connected to the lock body. The lock body further contains the power transmission mechanism. Publication CN 204571511 U describes a lock having a body which contains a deadbolt. The lock cylinder is connected to the lock body. The lock body further comprises a power transmission mechanism between the lock cylinder and the bolt. In addition, EP 2400083 A1 describes a lock having a lock body that includes a deadbolt. The lock cylinder is connected to the lock body. The lock body, according to this publication, also contains a power transmission mechanism between the lock cylinder and the deadbolt.

One way to influence the lock is drilling. By drilling, the aim is to break the lock so that its internal locking parts, for example the locking parts, can be moved, whereby the bolt can be moved out of the locking position. Various anti-drilling plates are used against drilling. The guard plate either seeks to completely prevent the drill from being fed into the lock, or is positioned so that the locking pin is displaced and the deadbolt cannot be moved out of the locking position. Known locks also have parts which, if broken or damaged by impact, cause the locking pin to be displaced so that the bolt cannot be moved out of the locking position.

Although the known solutions are workable as such, they require quite a lot of space and, moreover, they do not necessarily work well for other types of impact, such as impacts.

Brief description of the invention

The aim of the present invention is to provide an alternative solution to known locks, which further reduces or even eliminates the problems described above. The lock of the present invention is described in an independent claim. The dependent claims present various embodiments of the invention.

The lock according to the present invention is intended for locking cabinets, vaults and various machines. The lock has a body that contains a bolt. The lock cylinder is connected to the lock body. The lock body further comprises a power transmission mechanism between the lock cylinder and the bolt. The front of the lock cylinder contains the drill protection and the rear of the lock cylinder contains the latch. The power transmission mechanism contains a transmission lever and said latch. The transmission lever is rotatably connected to the latch at the first point of the transmission lever, and rotatably connected to the bolt at the second point of the transmission lever. The bolt contains a locking finger, and the lock body additionally contains a hole for the locking finger. The locking finger is spring-loaded so as not to enter the bolt, moving towards the hole in the locked position of the bolt. Opposite the locking finger, in normal use of the lock, there is a retaining lug to prevent the end of the locking finger from entering the hole.

The connection of the lock cylinder with the lock body and the connection of the transmission lever with the deadbolt are designed to allow the movement of the lock cylinder and the power transmission mechanism in the direction of the longitudinal axis of the lock cylinder. The lock also includes a spring located in normal use of the lock so as to hold the lock cylinder and the power transmission mechanism in place in the direction of the longitudinal axis of the lock cylinder. The spring is further positioned to allow movement of the lock cylinder and the power transmission mechanism in the direction of the longitudinal axis of the lock cylinder by impact from outside or drilling of the lock cylinder, whereby such movement in the direction of the longitudinal axis moves the retaining lug away from the locking pin. Therefore, the end of the locking finger is shifted into the hole to the locking position of the bolt.

Brief description of the drawings

The following is a more detailed description of the invention with reference to the attached drawings, where:

Fig. 1 is an example of a lock according to the present invention.

Fig. 2 - part of the lock according to FIG. one.

Fig. 3 is an example of a lock according to the present invention.

Fig. 4 - lock according to FIG. 3 with the rear surface removed.

Fig. 5 - lock according to FIG. 3 in partial section from the front surface of the lock.

Fig. 6 is a cross section of the lock according to FIG. 3.

Fig. 7 is an example of a lock in normal use.

Fig. 8 is an illustrative cross section of the lock in normal use.

Description of the invention

In FIG. 1 shows an example of one embodiment of a lock according to the present invention for locking cabinets, vaults and various machines. The lock has a body 1 and a bolt 2. Since the walls of cabinets, vaults and machines can be relatively thick, the lock can be equipped with a pivot link 21 of the lock cylinder 3 (FIG. 6). More specifically, the pivot link is for the key hole 24 of the lock cylinder and the key channel of the lock cylinder. The pivot link can extend from the lock through the wall of a cabinet, storage or machine to the other side. The length of the pivot link can be adjusted, for example, by means of a telescopic structure.

The lock is installed on the rear side of the wall of the cabinet, storage or machine, and the surface 1A of the lock is pressed against the rear surface of the wall. The pivot link extends to the front side of the wall. On this front side there may be a second lock cylinder, which can be actuated by a key 19 and is protected by an overlay 20. The second lock cylinder is connected to the rotary link 21.

The second lock cylinder is not shown in the drawings, but its structure may be that of a normal lock cylinder or a stripped-down structure without lock-specific levers/levers. The second lock cylinder thus connects the key 19 to the pivot link. In the embodiment of FIG. 1 lock cylinder 3 is an electric cylinder. Therefore, the rotary link contains an electrical connector 23 through which the electrical code of the key 19 can be transmitted to the cylinder 2 of the lock. If the code, i.e. the electric key, is correct, the electric lever(s) of the lock cylinder allow the key to be turned to open the lock. The pivot link transmits torque from the key to the lock cylinder. In a variant of the electric lock cylinder, the pivot link 21 also includes a key end 22 which fits into the lock cylinder 3, more precisely inside the lock cylinder 3 into its key channel. This key end has electrical connections to open the lock. In FIG. 2 shows the electrical connections 23 of the swivel link and the key end 22 in more detail. The front surface of the lock may have a mounting plate 25 which facilitates the installation of the pivot link 21.

The lock cylinder 3 may be a mechanical lock cylinder which holds known mechanical levers. Thus, the shaft of the key can be long enough to fit through a cabinet, vault, or car door into the lock cylinder to open it. Additionally, the structure of FIG. 1 can also be used without electrical connections 23. Therefore, the second lock cylinder, protected by a protruding escutcheon 20, contains mechanical levers, and the pivot link 21, having a key end, forms a mechanical connection with the lock cylinder. In this embodiment, the lock cylinder has only those specific levers that are positioned to work with the end of the key. Therefore, there are different ways to lock the lock cylinder and use it with a key.

Lock cylinder 3 and a second lock cylinder (not shown in the drawings) protected by a escutcheon are known lock cylinders, whether they are electrical, mechanical or perhaps adapted/simplified (i.e. used with a key head such as a blank key, etc.). If the wall of the cabinet, storage or machines is not very thick, it is not necessary to install the rotary link, since in this case the key 19 can enter directly into the cylinder 3 of the lock.

In FIG. 3-6 show an example of a lock according to the present invention for locking cabinets, vaults and various machines. The lock has a body 1 containing a bolt 2. The cylinder 3 of the lock is connected to the lock body. The lock body also contains a power transmission mechanism 4 between the lock cylinder and the bolt. The front part 4A of the lock cylinder comprises a drilling protection 5 and the rear part 4B of the lock cylinder comprises a pawl 6. The drilling protection is made of, for example, hardened metal. The power transmission mechanism 4 includes a transmission lever 7 and a pawl. The lock cylinder can be rotated by the key 19 inserted into it from the locking position to the open position and vice versa in a known manner. The lock cylinder can thus be rotated relative to the lock body. In the variant shown in the drawings, the housing 1 has space for the cylinder 3 of the lock.

The transmission lever 7 is rotatably connected to the pawl 6 at the transmission lever point 7A and is rotatably connected to the bolt 2 at the second transmission lever point 7B. The transmission lever further comprises a retaining lug 8. The bolt comprises a locking pin 9, and the lock body further comprises a hole 10 for the locking finger. The locking pin 9 is spring-loaded in the direction of the opening and, in the locking position of the bolt, is outside the bolt 2. The retaining lug 8 is located against the locking pin 9 during normal use of the lock, preventing the end 9A of the locking pin from moving into the hole 10.

Normal use means the locked state of the lock, the open state, and the movement between these states from one state to another. In the locked state, the bolt 2 of the lock is partially extended from the body, as shown in the drawings. It is often said that the end of the crossbar is extended from the lock. In the locked state of the installed lock, the end of the bolt enters the reciprocal structure of the machine, cabinet or corresponding storage, as a result of which the hatch / door of such a machine, cabinet or storage cannot be opened. Alternatively, the installed lock can be connected via a bolt to a separate bolt assembly, which in turn is included in the counterpart structure of the machine, cabinet or corresponding storage. The lock bolt locks the individual bolt assembly in the locking position or guides and locks the individual bolt assembly. The deadbolt 2 of the lock in the locked state can, in normal use, be moved to the open state with the key 19, while turning the cylinder 3 of the lock causes the pawl 6 to turn. 1 lock. The body of the lock has space for the bolt to move into the lock. Thus, the bolt is moved from the locked position to the open position, whereby the lock enters the open state. In the open state of the installed lock, the hatch / door of the machine, cabinet or storage can be opened. By turning the key in the opposite direction, the bolt, respectively, can be moved from the open position to the locking position, as a result of which the lock goes into the locked state.

The first point 7A of the transmission arm 7 is usefully placed at one end of the transmission arm. The second point 7B, in turn, is usefully placed near the opposite end of the transmission arm. It is also useful to place the retaining lug 8 at the opposite end. Such an option is shown in the drawings. The shape of the profile of the retaining protrusion 8 is, for example, round, but it can also be other, for example, semi-circular.

The connection of the lock cylinder with the lock body 1 and the connection of the transmission lever 7 with the bolt are made so as to allow the movement of the lock cylinder 3 and the power transmission mechanism 4 in the direction of the longitudinal axis of the lock cylinder. The direction of the longitudinal axis is shown in the drawings by dashed line A. The lock also includes a spring 11 which, in normal use of the lock, holds the lock cylinder and the power transmission mechanism 4 in place in the direction of the longitudinal axis A of the lock cylinder. The spring 11 further allows the movement of the lock cylinder 3 and the power transmission mechanism 4 in the direction of the longitudinal axis of the lock cylinder by an external impact or drilling of the lock cylinder, and as a result of this movement, the holding protrusion 8 is displaced from the locking pin 9. Thus, the end 9A of the locking pin is shifted into hole 10 in the locked position.

The spring 11 is pressed against the rear wall 1B of the lock body by the lock cylinder when drilling is performed in the direction of the lock or the lock is hit with sufficient force, causing the lock cylinder 3, the pawl 6 and the transmission lever 7 to shift. The drawings show how the spring 11 is located between the outer lock cylinder 3A and the lock body 1. When the inner cylinder 3B is subjected to a drill or impact, such drilling/impact also affects the outer cylinder through the rear end 29 of the inner cylinder, causing the entire lock cylinder to be displaced, compressing the spring 11. FIG. 6 shows how the lock cylinder 3 has moved towards the rear surface 1B of the lock body by drilling or impact force, leaving a free space 28 in front of the front part 4A of the lock cylinder.

The spring 11 thus, in normal use, holds the lock cylinder in place in the direction of the longitudinal axis of the lock cylinder 3. The direction of the longitudinal axis is shown in the drawings by dashed line A. The spring, in normal use of the lock, simultaneously holds the power transmission mechanism 4 in place in the direction of the longitudinal axis.

Thus, if the drilling is directed from the outside to the inside of the lock, and the drilling is aimed at eliminating the locked state of the lock by drilling the lock cylinder 3, the drill protection 5 prevents the drill from moving deeper and, therefore, the drill has to be pressed against the cylinder and the lock more. Thus, the anti-drill protection is designed to prevent the drill from being fed forward if it has already penetrated from the outside before the anti-drill protection. Therefore, the spring 11 is compressed and the lock cylinder 3 can move in the direction of its longitudinal axis towards the rear wall 1B of the lock body. The spring, of course, can be compressed already at the initial stage of drilling. Since the pawl 6 is fixedly connected to the lock cylinder 3 and also connected to the transmission lever 7, and the connection between the transmission lever and the deadbolt 2 allows the transmission lever 7 to move in the direction of the longitudinal axis of the lock cylinder, the power transmission mechanism 4 is also simultaneously shifted towards the rear wall of the lock body. . The corresponding movement of the lock cylinder 3 and the power transmission mechanism 4 occurs if the lock is acted upon by a strong enough stroke. The retaining lug 8 simultaneously moves away from the locking pin 9 and the locking pin moves into the opening 10 when the bolt is extended, i.e. is in the locked position.

As shown in the drawings, the bolt 2 has a space 12 in which the second spring 13 and the locking pin 9 are installed. The second spring 13 pushes the locking pin 9 out of the bolt, but in normal use the retaining lug 8 prevents the locking pin and in particular its end from coming out. 9A from the crossbar. This space is thus connected to the crossbar surface 2A. This surface of the bolt also has a side groove 14 which extends into the space 12. By means of this groove, the retaining lug 8 is pressed against the locking pin 9 during normal use of the lock. normal use. This lateral groove 14 allows such movement.

In the variant shown in the drawings, between the transmission lever 7 and the pawl 6 there is an axial swivel 15, which has an axial pin 16 and a hole 17 and in this connection the pin enters the hole. The hinge 15 remains in place in the direction of the longitudinal axis of the lock cylinder. Therefore, if the lock cylinder 3 moves in the direction of its longitudinal axis, the transmission lever 7 also moves simultaneously and in the same direction of the longitudinal axis of the lock cylinder. The swivel joint 15 may comprise a so-called snap-on connection, where the pawl 6 and the transmission arm 7 are snapped onto each other. In the embodiment shown in the drawings, the pin 16 of the swivel 15 is part of the transmission arm, and the hole 17 is made in the pawl, but this arrangement can be reversed, i. the transmission lever may contain an opening and the pawl may contain a pin.

Between the transmission arm 7 and the bolt 2 there is a second swivel 16A, which has a second axle pin 17A and a second hole 18, and in which the axle pin 17A is inserted into the hole 18. The second swivel allows the gear arm 7 to move relative to the bolt 2 in the direction of the longitudinal axis lock cylinder. In this way, the transmission lever 7 can slide relative to the deadbolt in the direction of the longitudinal axis of the lock cylinder. In the embodiment shown in the drawings, the pin 17A of the second swivel 16A is part of the transmission arm, and the hole 18 is made in the bolt, but this arrangement may be reversed, i.e., the transmission arm may contain a hole, and the bolt may contain a pin.

The connection between the pawl 6 and the transmission arm 7 may also be a toggle connection which is in lock mode when the bolt is in the lock position. Such a knee-lever connection is shown in the drawings. The toggle joint in the locking mode does not allow the end of the bolt 2 to be pushed into the lock body, since the toggle joint does not allow the pawl 6 and the transmission lever 7 to turn. The drawings also show a third spring 27, which tends to keep the power transmission mechanism in the locking position, when the latch is in the locked position. The lock may also have a switch 26 (eg, a microswitch) that can monitor the power transmission mechanism, such as whether it is in the locked position or the open position.

In FIG. 7 and 8 show an example of the normal use of the lock when the bolt 2 is extended to the locking position. As shown in FIG. 7, during normal use of the lock, the retaining lug 8 is pressed against the locking pin 9, preventing the end 9 of the locking pin from being displaced into the opening 10. In FIG. 8 shows the position of the lock cylinder 3 relative to the body 1 in normal use. Thus, there is a space 80 between the pawl 6 and the rear surface 1B of the lock body, which allows the lock cylinder and power transmission mechanism to move towards the rear surface 1B if the lock is to be drilled or struck. In FIG. 4-6 shows the situation when the lock is subjected to drilling or impacts.

The present invention makes it possible within the lock body 1 to provide a secure device for releasing the locking pin 9 if the lock is drilled or struck. Since such a device is connected to a deadbolt or uses a deadbolt, a power transmission mechanism, and a lock cylinder, it is compact and takes up little space. The lock of the present invention can be implemented in various ways, as follows from the above description. Thus, the invention is not limited to the examples presented, but can be carried out in various ways that fall within the scope of the independent claim.

Claims (14)

1. A lock for locking cabinets, storages and various machines, containing a body (1), which has a bolt (2), and a lock cylinder (3) connected to the body, while the lock body additionally contains a power transmission mechanism (4) between the lock cylinder and a bolt, characterized in that the front part (4A) of the lock cylinder contains a protection (5) against drilling, and the rear part (4B) of the lock cylinder contains a pawl (6), and the power transmission mechanism includes a transmission lever (7) and the specified pawl, wherein the transmission lever is rotatably connected to the pawl (6) at the first point (7A) of the transmission lever and connected to the crossbar (2) rotatably at the second point (7B) of the transmission lever, in this case, the transmission lever additionally contains a holding ledge (8), and the bolt contains a locking pin (9), and the lock body contains a hole (10) for the locking pin, while the locking pin (9) is spring-loaded in the direction from the bolt (2) to the hole (10) in the locking position of the lock, and the retaining lug (8) is pressed against the locking pin (9) during normal use of the lock, preventing the end (9A) of the locking pin from moving into the hole (10), and the connection of the lock cylinder (3) with the lock body (1), and the connection of the transmission lever (7) with the bolt (2) allow the movement of the lock cylinder (3) and the power transmission mechanism (4) in the direction of the longitudinal axis of the lock cylinder, wherein the lock further comprises a spring (11) located to hold the lock cylinder (3) and the power transmission mechanism (4) in place in the direction of the longitudinal axis of the lock cylinder (3) during normal use of the lock, and to allow movement in the direction of the longitudinal axis under action of external impacts or drilling of the cylinder (3) of the lock, whereby movement in the direction of the longitudinal axis shifts the retaining lug (8) away from the locking pin (9), which allows the end (9A) of the locking pin to move into the hole (10) in the locked position of the bolt ( 2). 2. The lock according to claim 1, characterized in that the bolt has a space (12) in which the second spring (13) and the locking pin (9) are located, while the second spring pushes the locking pin out of the bolt (2). 3. The lock according to claim 2, characterized in that a side groove (14) is made in the surface (2A) of the bolt, passing into the space (12), and with the help of this side groove, the retaining protrusion (8) is pressed against the locking pin (9) during normal use of the lock. 4. The lock according to claim 3, characterized in that it contains an axial swivel (15) between the transmission lever (7) and the pawl (6), which contains an axial pin (16) and a hole (17), while in the axial swivel the axial pin is placed in the hole, while the swivel (15) is maintained during movement in the direction of the longitudinal axis of the lock cylinder (3), due to which the transmission lever (7) moves in the direction of the longitudinal axis of the lock cylinder. 5. The lock according to claim. 4, characterized in that it contains a second axial swivel (16A) between the transmission lever (7) and the bolt (2), which has a second axial pin (17A) and a second hole (18), while in In the axial hinge joint, the axial pin is placed in the hole, while the second axial hinge (16A) is configured to allow movement of the transmission lever (7) relative to the bolt (2) in the direction of the longitudinal axis of the lock cylinder. 6. The lock according to claim 5, characterized in that the connection between the pawl (6) and the transmission lever (7) is a toggle joint, which is in the locking mode when the deadbolt (2) is in the locking position. 7. The lock according to any one of paragraphs. 1-6, characterized in that the protection (5) against drilling is made of hardened metal. 8. The lock according to any one of paragraphs. 1-7, characterized in that it contains a rotary link (21) of the cylinder (3) of the lock, which is configured to pass from the lock through the wall of the cabinet, storage or machine to the other side. 9. The lock according to claim 8, characterized in that the pivot link (21) has a key end (22) which extends to the lock cylinder (3).

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